Means for forming pressed articles from powders



MEANS FOR FORMING PRESSED ARTICLES FROM POWDERS Original Filed Oct. 18,- 1940 12 Sheets-Sheet 1 JOSEPH .S'. PEG/(ER 8" HE NE) A. S/MPSO/V Sgpt 7, 1948. J/S. PECKER ET AL 9,

MEANS. FOR FORMING PRESSED ARTICLES FROM PQWDERS Original Filed Oct. 18, 1940 l2 Shegts-Sheet 2 5 JOSEPH s. PEG/(El? a HE/VR) A. SIMPSON p 7, 1948. J. 5. PE-CKER ET'AL V Z,449,008 i MEANS FOR FORMING ERESSED ARTICLES mom POWDERS Original Filed Oct. 18, 1940 12 She et's -Sheet s J. 5. PEGKER ET A 2,449,008

12 Sheets-Sheet 4 3M JOSEPH s. PEG/(ER a HEM-77A. SIMPSON Sept. 7, 1948.

MEANS FOR FORMING PRESSED ARTICLES mom rownnns Origina l Fiied Oct. 18, 1940 4 W w mw/ M Sept. 7, 1948. J. 5. PECKER ETAL 2,449,008

MEANS FOR FORMING PRESSED ARTICLES FRO M POWDERS Original Filed Oct 18. 1940' l2 Sheets-Sheet 5 1 L I WWW 62 64 65 r Sept. 7 1948. 3. s. PECKER ETAL 2,449,008

MEANS FOR FORMING PRESSED ARTICLES FROM POWDERS Original Filed Oct. 18, 1940 12 Sheets- Sheet 6 HH- A1 D x ml Maw q v w 1 5 3 ..n 7 WNW. WW

80 40 83 %E&

Sept. 7, 1948. .L s PECKER ETAL 2,449,008

MEANS FOR FORMING P RESSED ARTICLES FROM POWDERS Original Filed Oct. 1a,v 1940 12 Sheets-Sheet a JOSEPH s. PEG/(ER a HENRY A. S/MPSO/V M KY-W WWW) Sept. 7, 1948;

' J. s. PEJQKER ETAL mmms Fox Fonmiw PRESSED-.ARTIGLES mom rowmsns Original Filed Oct. 18, 1940 l2 Sheets-Sheet l2 JOSEH-l s. PEG/(EH &

HENRY A. SIMPSON @Q MW v i operations.

Patented Sept. 7, 1948 MEAN S FOR FORMING PRESSED ARTICLES FROM rownsns Joseph s. Pocket and HenryA. Simpson, Philadelphia, Pa.; said Simpson assignor to said Packer Original application October 18, 1940, Serial No. 361,656. Divided and this application December 27, 1943, Serial No. 515,790

1 'Olaims. This invention relates to a means for forming pressed metal articles from powdersorganic,

metallic or' mineral.

An object of the invention is to provide a machine for forming an article in separate pressure operations and to unite the parts so formed by pressure weld, or prior to other processing such'- as sintering as shown in our co-pending application, Serial No. 341,830, now Patent No. 2,271,091. j i

A further purpose is to provide a machine for formingan article of powdered alloy or the like by pressure in the direction of its lesser dimension, whereby a comparatively short pressure stroke can be employed, and by a plurality of such short stroke formations finally produce a piece having greater depth than breadth.

A further purpose is to provide a machine for automatically measuring the amount of powder used'in each operation, and for manipulatingthe powder priorto compressionso as to create separate areas of powder in relation to the finished article throughout the several required pressure A further purpose is to provide-a machine havin multiple plungerdies orpunches which are operable from above, below, and from the sides and at various angles, to create predetermined areas of powder, and means to utilize the same plunger dies to press the powder to the desired shapewithin cavity dies and to pressure weld the separately formed portions together.

.A further purpose is to provide orifices'within the initial formation to receiveand hold powder introduced in subsequent operations to assist in the union of a subsequent formation by pressure weld. A further purpose is to provide a practical means for accomplishing the objects set forth, first, in a complete automatic and continuous machine and, second, in a complete automatic machine having an. intermittent movement.

A further purpose is to provide automatic mechanism for redistributing the powder within cavity dies after filling, so as to create areas obtained.

These and further purposes will become evident by utilizing the mechanism hereinafter more fully described and illustrated in the accompanying drawings, wherein like numerals refer to similar parts throughout the several views, of which I Fig, 1 is a plan view of our improved device, showing the intermittent type design;

Fig. 21s a transverse section taken on line 2-2 of Fig. 1; s V

Fig. 3 is an enlargedfragmentary sectional detail of the first hopper and a forming die associated therewithin the relative positions occupied at station A, Fig. 1.

Fig. 4 is a vertical section on the line 4-4 of Fig. 3.

Fig.5 is a section similar to Fig. 3 but showing the several parts as they would appear when associated with the second hopper at station D;

Fig. 6 is a vertical section on line 6-6 of Fig. 5;

Fig; 7 is a sectional elevation similar to Fig, 3,

showing the relative parts in the positions oc- (mined at station 3;

Fig. 7A is a f Fig. 7;

Fig. 8 is a fragmentary sectional elevation horizontal section on line IA-4A taken on line 8-8 of Fig. '7;

positioned at station E;

. Fig. 13 is a sectional elevation taken on line I3- |3 of Fig. 1;

14 is asectional'elevation taken on line I4--l4' of Fig. 12; 1

Fig. 15is a detailed fragmentary planview. of

a die block when positioned at station F;

Fig. 16 is a sectional elevation taken on line Fig. 17 is a plan view, similar to Fig. 1, showing the continuous type of machine;

of a reciprocating piston rod. supporting. powder preformed during and by the movement .ofithe Fig. 18 is a sectional elevation, similar to Fig. 2, and taken on line l8-|8 of Fig. 17;

Fig. 19 is an alternate arrangement of horizontal punches within a die block;

Fig. 20 is an elevation, partly in section of a modified form of multiple vertical punch, operable above the die block by an eccentric motion;

Fig. 21 is a sectional elevation of a modified form of. multiple horizontaLpunch, taken on line 2 l.2' i of Fig. 22;

Fig. 22 is a side elevation of the parts illustrated in Fig. 21; v

Fig. 23 is a perspective View of the piece a formed by the initial pressure operation of the machine, showing a front, side and bottom therei Fig. 24 is a similar view illustrating in full lines the second formation, while the first formation is indicated in dot and dash line in its relative connected position;

In order to clearly illustrate the operation of the machine, one of the forming dies and its various coacting component parts is separately shown in association with each of the several operating stations, as the piece is progressively formed.

The particular piece here shown has been chosen merely as an illustration of the range of capabilities of the machine, and is in no way to beconstrued as, a limitationto... this individual design. It'= has been chosen as a representative product because of its variety of surface contours,

including indentures and pierced openings, be-

ing formed by vertical actions both from above and below, and by horizontal actions from both sides and includes the formation of angles.

I Analmostendless; variety of articles can be Fig. 25 is a top plan view'ofthe piece-shown;

in Fig. 23;

Fig. 26 is a bottom plan view of the unde-r face of the punch for forming the piece shown inFig. 23; Y Fig.- 2? is a fragmentary sectional, elevation of ai cavity. die and plungers in the relative positionsoccupied at station A;

. Fig, 28 is a sectional elevation taken on line X--X of Fig. 2'?

Fig. 29 is a sectional elevation taken on line Y-Y of Fig. 27;

Fig. 30- is a sectional elevation taken on line Z-Z of Fig. 27;

Fig 31.is a view. similanto Fig. 27 showing. the parts-in the. relative positions occupied at stat Qn-B;

Fig. 32 is a sectional elevation taken on line X-Xpf Fig. 31;

Fig. 33 is a sectional elevation taken on line :Y -Y of Fig. 31;

. Fig. 34 is a sectional elevation taken on line Z Z ofFig. 31;

Fig. 35-is a viewsimilarto Fig. 27 showing the parts in the relative positions occupied'atsta- .tionE;

X -X of Fig. 35;

Fig. 37 is a sectional elevation taken online, Y,-.-Y. of Fig. 35;

Fig. 38 is a sectional elevation takerron line Z-Z of Fig. 35; Fig. 39 is a fragmentary-sectional elevation disturbing fingers andcooperating mechanism; Fig. 40 is a view similar to Fig. 39 illustrating the powder disturbing fingers entered into vthe powder area;

Fig. 41 is a view similar to Fig. 39 showing the fingers having been moved while in the powder l rea;

Fig. 42 is .a fragmentary sectional elevation,

taken on line 42'42 of Fig. 39; and

Fig. 43 is a sectional plan taken on line 4343:

Referring now to the drawings, and especially *to- Figs. 1 and 2, it will be observed the. general stations at which several of the, operations ;take

placesimultaneously, while other operations are head between theseveral stations.

machine or the. method of forming.

Attention is here drawn to the fact that the successivejstages of" formation of the piece are 'all-madein the; direction of its lesser dimension.

Thisis desirable in articles requirin a plurality ..of.operations to complete the piece, as a far more uniform product is thus obtainable and an even density is assured. It is a purpose of Our device and a method employed thereby, whereby desired dimensions in one direction are obtained by a plurality of short strokeoperations, and the several independent formations successively welded together by the pressure, of each succeeding stroke. v

In the drawings, only the. required number of stations to form the particularpiece illustrated are shown, namely, six (6). It will be. under.- stood, however, that in a commercial interchangeable machine, an'additional number of stations would be present to ,take care of articles requiring more operations in their formation,

such as that illustrated in-Figs. 39 to 43 inclusive.

Those stations not .used in the formation of; a piece requiring. less operations would merelybe left as idle stations.

The six stations here illustrated are respectively. designated in the drawings by the letters A-BC-DE and F A-representing that'sta- 'tionat which thetpowder alloy'is first measured where top and side compressions are employed; and F, where the mandrels are moved out, the

die opened and the finished product ejected therefrom, to be moved off later by contact with a fixed plate arranged atan angle in its ad- "vancing path. The. two latter movements, the

withdrawal of "the-mandrels and the opening of the die block, take place between stations and during the forward rotation of the head, so that ;if it were not for required timing, the present machine would be operated with five stationsto a cycle. The rotatable head is indicated at 30, suitably si p portedand, guided by, bearin members 3|,

and. having roller bearings 32suitably placed to assist in the rotation ,of the head. The head .30 alsocarries a centrally arranged vertical shaft, 33 which is supportedat its base in a suitable cast.- ing. 34. This'shaft 33 has fastened thereto the driven element 35 of a well-known Geneva m0.-

tion, the driving element 36 being connectedto any suitable power source, not shown. Gertain of the bearing members 3| extend above the rotatable head at stations B, C and E, and support fluid operated pistons 31 of any wellknown type, which when operated, control the pressing andypositioning operations, while the bearing members 3| at stations ,A and D likewise extend above the rotatable head and respectiveby support hoppers 50 and 50A containing a supply of powder.

The head carries a'p'lurality of die blocks 40, one for each operating station and they areadvanced the distance between one station with each turn of the driven element of the Geneva motion, each die receiving a charge of powdered metal during its dwell at station A and then being advanced intermittently to each subsequent station and being subjected to the various required operations until each of the finished articles are ing a cross-sectional area in a given proportion to l the finished compressed piece. Further, the forward movement of the head 30 also causes the operation of the mechanisms which control the insertion and withdrawal of mandrels, as well as the opening of the die blocks to release the piece. r

7 Assuming a die block has just been presented to station A (referring'to Figs. 1, 2, 3 and 4) and it is brought to a dwell beneath the powder feeding hopper 50, the powdered material flows by gravity from the hopper into the various cavities of the die indicated at 5| and 52and formed by the positioning of a plurality of plungers 53, 54 and 55. I These plungers are respectively controlled by cams 56, 51 and 58 designed to cause themto rise and fall as the head 30 is advanced. The cams are fixed and arranged in circular paths, one beneath each die plunger, and are so designed as to cause the plungers to operate independently of one another and at such times as to cooperate with the preforming of powder areas in a given relation to the several compression movements hereinafter described (see Figs. 2, 7 and 13).

With the die adjusted as shown in Figs. 3 and 4, and filled with powder, it is advanced to the next station B. During this advance, the powder is prevented from leaving the bottom of the hopper by the top of the head 30, which lies flush with the top of each die block 40, so that the bottom of the hopper is always closed except at those times when a die cavity is aligned With it.

At station B, the supporting frame 3| is built up above the turn-table 30, to support one of the fluid driven pistons 31B. These pistons are controlled and operated from the usual organ or control board common to hydraulic machines, and are designed to automaticall make on reciprocating stroke as the turn table or head 30 comes to rest with the dies aligned with the plungers by the Geneva motion.

All the piston plungers operate in unison and are suitably guided in their respective frames 3|, each being provided with a cross head 38B, 38C or 38E, the outer free ends of which carry depending studs 39B, C or E which, in turn, actas guidesfor 6 thezres'pective punches carried on each plunger. At station E, the studs 39E have an additional function, that of operating horizontal dies, which operation will. be ,laterdescribed in connection with that particular station.

With the die plungers.5354 and 55 positioned by their respective cams as seen in Fig.7, the piston plunger 31B descends and punch 4| com.- presses thepowder to a shape P, such as illustratedinFig. 23. a l

To further assist in the union of the separately formed parts, We provide depressions in the initial formation as seen at 42, Fig. 7, which are filled with powder at the second loading, and under the second compression, tend to fuse with the initialv1y formed piece. During a subsequent sintering operation, to which all such formations as here disclosed are subjected, the parts are fused to, gether in a homogeneous mass, and the point of union becomes as stron as any other portion of the piece.

In pieces which require more than tWo operations to complete, each section is provided with depressions as aforesaid with the exception of, the last, Which being the topmost, has no require.- ment for same and is finished to desired shape by the final, compression stroke.

- We have discovered that the creation of increased areas of powder in relation to the formation of these depressions, aids materially in the strengthening of the points of union during pressure weld and an increased density is thereby obtained at these points. To this end, We have devised the mechanism shown in Figs. 39 to 43 in. elusive, which. can be positioned at additional stations following each powder feed and operated for the purpose of distributing or repositioning the powder within the die cavities in relation to the subsequent pressure of plungersor punches.

The device is, further useful to assist in arranging the second and/or subsequent powder introductions in such manner, within the die cavity, as to position the powder for maintaining the correct ratio of powder to required plunger strokes following the introduction of the mandrels. V In the present instance, We will assume the mechanism to be operated from a piston the same as the other plungers at stations B, C and E, it being understood that the stroke is synchronized with the dwells the same as at the other stations, and that the type of operating mechanism is immaterial so long as it produces a single cycle and pauses until tripped again for a repeating operation. Such a piston rod is shown at 31M reciprocatably supportedin frame 3| and carrying at its lower end a slidable casing structure 31N having an internal contour corresponding to the cavity opening ,within die block 40. i

This casing is held within the piston 31M by two shafts 310 each of which forms the fulcrum for a finger 31F. These fingers are of oppositely opposed formations designed to rest normally back to back and be retained in this position by tension springs 3IQ. Extending from the hub of each finger structure and in line with the respective shafts 310 is a, pin 31R, the outer free end of which rides within a slot 315 formed in the side Walls of the slidable casing MN. The casing 3'1N is further provided with slots 31T surrounding each of the supporting shafts 310.

The lower end of each finger structure 31]? is shaped, in the present instance as at 31U, it being understood that the design may vary with the requirements of the piece being formed.

In operation, thepiston rod- SIM-1s normally suspended as shown-in Fig, 39 and w-l'ien-the'e die block is-brought to dwell beneath-it; the piston is caused to descend until-the lower ends 31U of the fingers 31? enter the powder within-the die cavity. About thesame time the casing 3IN has contacted with'thetop of die block 40, as clearly shown in Fig. 40, preventing' an y powder displaced by the fingers 31F frombeing moved from out the area of the cavity.

Further downward movement of the plunger 31M and therewith the shafts 310,'causes the .projecting pins 31R, resting within slots 31S-to rotate the hubs of the respective fingers '31P about their shafts 37C) causing the free ends of the fingers to move outwardly away froin eac'h other against the tension of springs 31Q as clearly illustrated in Fi 41. 4

This latter movement, is very slight being limited by the length of slots'3'lT within the sliding casing 31N (see Fig. 42) which slot permits the further movement of plunger BIM after the easing 31N has contacted thetop of die block 40. It will be observed by the position of the powder within'the die cavity in Fig. 41 that the powder is now hilled up in those areas in which it is desired to unite the separate piece formations by pressure weld, and wherein subsequent depressions are formed to assist in this pressure welding operation.

As the piston rod NM-starts its return movement, the two shafts 310- move therewith riding in slots 31T and the springs 31Q draw the fingers 31F toward each other, until they meet (as in Fig. 40), the projecting pins 31R riding in slots "313. As soon as the shaft 310 engages the'top'of slots 31T,the sliding casingtlN'is picked up and moved with the piston rod 31M back to the normal rest position illustrated in Fig? 39; whereit is held until the piston is again operated for another cycle as just described.- 1

This same mechanism is also applicable to-preformations of powder within thecavities to maintain ratios after man'drels have been in serted and the lower die plungers are no longer capable of this work.

With the completion of the initial pressing of the piece at station B, head '3lland therewith the die block' io is advanced't'o the next station C which is illustrated in section at the right side of Fig.2. Here the piston plunger =3-TC'is caused to move down through its hydraulic control; car'- rying therewith a punch 43 designed to contact the piece P as formed at station Band-move'the same to a lower level. The new position ofthe piece permits of the insertion-of a pair of man-' drels 44-45 above this formation, which insertion takes place during the advance of the" head 30 to and before reaching the next stat'ion;

These mandrels are provided with -interfltting ends 48'48 which are designed to overlap and unite to form a joint as at- 49'- (Fig. 14) when in closed position, sucha, joint providing strength at apointof pressure, thereby avoiding sheering by the upper punches. The spring pressedends 44A and A are designed to cooperate wlth the ends of their respective mandrel-s-to-close the walls of the die cavitywhen the -mandrels "are in their withdrawn positions and to be moved out of the travel path of the mandrel endswnentne latter'are moved to theire-ng-aging position.

Referring now to Figs. 9, 10- andll jthe mandrels 44 and 45 are'in'dicated in their outposition', i-. e., disengaged from-the forming portion of die block 40 and are respectively positioned within enta ls-=41; formed in the block} Theinrier end of each mandrel is shaped to cooperate with the forming dies while at the outer free end thereof is formed a slotted head portion 69, adapted to receive a pin Bl eccentricall'y mounted on a stud 62. These stud shafts are positioned in openings 63 formed in the head-30, and their lower ends are of decreased diameters toprovide f-or coil springs 64, and pinion's 65, the latter being-fixed to the studs while the spring has one free end fixed to the stud and the oppo= site free end'fix'ed within the head 30 in such manner as to tend to-turn the stud in the direction of the full line arrow, Fig. 9, thereby normally forcing the mandrels toward one another.

Cooperating with pinions 65 and guided within suitable slots in head 30, are racks 66, the outer free ends of which extend beyond" the outer periphery of head 30 and carry rollers GT--68 thereon, said rollers contacting respectively with cams-69'l0, fixedly supported upon the bearing members 3|. 7 4

The m-andrels are normally held out of their operative position by the action of cams 69-40 causing the rack arms 66 to move inwardly against; the action of their respective springs 64', moving pins '6! eccentrically within slots 60 to move the mandrels away from engagement with the dies. When any given die block moves be yond station C, cams 59-10 permit the rollers 6|-68 on racks 66 to move outwardly under the urge of the coil springs 64, and permits the turn ing of stud shafts 62 and their eccentrically mounted pins 61, said pins riding in slots 60 of the respective mandrels, urge the latter to closure in relation to the forming dies and above the initially formed piece P, as clearly seen in Figs. 5-and 6.

Before the die blocks reach station D under thesecond 'ho'pper 50A, both mandrels 44 and 45 have closed to form joint 49 over the piece P and are in position to assist in the second oper'; ation, or the formation of piece P2. With'the mandrelsiri this closed position, powder is introduced'to the die during its pa'use at station D, as seenin Figs'5 and 6. With powder intro duced for the second time, the die is again ad vanced to station E, where the point of final compression (in the case of a two-compression piece) takes place. I

As before stated, the action of the fluid operated piston 31E at this station is identical with that of the corresponding pistons at stations B and C. I

Referring now to Figs. 12, 13 and14, a crosshead 38E carries at either outer end depending studs 39E adaptedto enter openings 15 formed in the die block 40 and of corresponding shape and size to the studs. The cross-head also carries a punch 16 designed to cooperate with the die opening formed within die block 40 and the mandr'els' 44 and 45, to compress the powder injected at station D to the shape shown at P2 and to fuse or pressure weld the portion'Bz to the portion P initially produced.

It will be understood that in' all the changes of die shapes, the respective cams 56, 51 and 58 are designed to cooperate with the several required movementsof the die plungers 53, 54 and 55 and between each station the various movements to-efiect' the required changes take place during the advancement of the head-30, so that these dies have been properly positioned prior to theirarri-val'at their points of dwell.

At' this station; horizontal punches are op'eratedto provide depressions of different diameters in each side of the piece. This is accomplished by the introduction of punches 8080 and 8l'8l, slidably fitted within openings 82 formed in the die block '49 and head 30. These punches are normally held away from the piece in formation by expansion springs 83-43, and are forced inward toward the piece by the action of slotted cams 64 formed in the depending studs 39E, coacting with pins 85 fixed in the punches.

In the present instance, four plungers are provided as .will be seen by referring to Fig. 12, and their actions provide depressions of different diameters in each side of the finished piece. It will be understood, however, that the size and nature of the work accomplished by this action is limited only by the design of the punches, and they may be made to pierce as well as depress. If desired, the punches 8@8| could be arranged radially about the die block as illustrated in Fig. 19, and caused to operate on various faces of the piece in formation.

We further appreciate the possibilities of using multiple punches in association with this horizontal action, both in proportioning the powder prior to compression and to complete the pressure stroke. An example of such an arrangement is shown in Figs. 21 and 22, wherein a central punch 60A is surrounded by a punch 8IA, each spring .pressed away from the piece and moved to the work bycoacting cam faces 85-86, located respectively on the outer free ends ofthe plungers and the lower ends of depending studs 39A. The shapes of these cams can be designed to create a variety of actions and relatively time the strokes of the punches, and the length thereof. 7

The withdrawal of the studs 39E permits the springs 83 to move the punches away from the work, so that they are automatically withdrawn simultaneously with the withdrawal of the punch 16. r

In the production of the present piece, the compressing is now completed, and the die block 49 is carried forward to the next station F. Prior to its arrival, the cams 69 and 10 are shaped to force the racks 66 inward, turning studs 62 through connection with pinion 65, and therewith the eccentrically positioned pins 6| in slots 60 to cause mandrels 44 and 45 to be withdrawn from the finished piece.

About the same time, a grooved cam 99 simie larly mounted to the cams 69-10, guides a roller 9| attached to the outer free end of an arm 92 which, in turn, is connected to a separable portion 40A of the die block .40, to cause. the forming dies to separate. (See Figs. 1, and 16 for separated position, and Figs. 2, 3,5, 7, 9, 12 and 13 for closed position.)

The completed piece comprising the initial formation P and the final formation P2, pressure welded together, is now relieved of side pressure and the mandrels have been withdrawn, leaving the piece resting on top of the three plunger dies 53, 54 and 55 and below the upper face of the die block 40. As the head '30 is again advanced, the cams 56, 51 and 58 cause their respective plunger dies to rise and carry the finished piece to the level of the top of the die block, holding it in this position until it is advanced to a wall 95 arranged in its path of travel (see Figs. 15 and 16). The continued forward movement of the head cooperating with this wall, earns the finished piece from the die and off the. die

block to be taken up upon a chute 96 or other suitable conveying means to carry the completed piece' away fromv the head. The die plungers 53, 54 and 55 are then moved during the remain der of this travel to the respective positions occupied at the beginning of the cycle, and when they reach the next station A, they are again positioned to receive an initial charge of powder as previously described and illustrated in Figs. 3 and 4.

Coincident with this final movement of the die block, the cam 90 causes the roller 9! and therewith arm 92 to move inward and force the separable portion 40A of the die block to closure. Itwill be understood that the various operations are all taking place simultaneously, and that the several mechanisms are operating in unison uponea'ch of the die blocks as they are successively presented to the several stations. In the following description of the operation, we will take one individual die block and advance it through its particular cycle from the initial powder introduction to the final ejection of the finished piece.

Starting at station A, we will assume that the die we have selected to follow through a cycle of operation has just been presented at that point with the parts in the relative positions indicated in Figs. 3 and 4. Under the influence of. the Geneva motion, the head 30 and therewith the die block 40 pauses beneath hopper a sufficient length of time to permit powder to flow from the hopper and fill the cavities 5l and 52, the

- relativepositions of the die plungers 53, 54 and 55 determining the amount of powder the cavities will hold, and therelative positioning of the powder therein.

The shape of the bottom of the hopper in plan is the same as that of the cavity in plan. Due to the relative constructions of the head 30 and the bottom of hopper 50, when the cavities are filled, powder can no longer flow and the supply within the hopper is stopped from feeding by the powder within the die. The depth of the cavity die asdetermined by the positioning of the respective die plungers, acts as a means to measure the amount of powder required in each of the separate areas within the cavity to establish a given ratio of powder to finished piece, thereby assuring an even density throughout the pressed piece, and at the same time prevent overloading which might result in breakage of punches or mandrels.

With the first advance of the head 30 (stations A toB'), a separation of the powder will occur on'a line along the top of the die block and the bottom of the hopper, the flush top of the advancing die block contacting beneathfithe stationary hopper and preventing the powder therein'from=leaving until the-next succeeding-die block and cavity is brought into register.

As the head makes its advance to the second dwell position, the die plungers 53, 54 and 55 are moved and finally brought to rest in the respective positions illustrated in Fig, '7. The fluid operated pistons are now energized during the dwell, the head 31B descending, the depending lugs 39B entering guide openings 15, assist in positioning upper forming punch 4| to enter the die and com press the powder to the formation P. With the completion of this compression, the fluid pistons 3Tstart their up stroke, the punch and depending guide pins withdrawn and the head is again 1 l. advanced (stations B to'C) by the Geneva motion.

During this advance, the piston plungers :53, 54 and 55'are droppedin unison, the distance of the thickness of the mandrels 44 and 45 (Fig. 2).

At the dwell at station C, the head 310 is caused to descend, depending studs acting to guide-the punch 43 to within the die and-move the piece P to the lower level determined by'the die plungers, This accomplished, the punch is withdrawn by reverse action of piston plunger 31--C,'and the head is again advanced (stationsC to 'D) As the head and therewith die block is now advanced, cams 69 and 10 permit the racks '66 to move outward urged by'action of springs 64, through their stud and'pinion connections and at the same time cause the eccentrically mounted pinslil through their slot connectionszGO to move the respective mandrels 44-45 toward one'another until they close over and within the previously formed piece P, the. mandrel ends being designed to cooperate with the die formations (see Figs. 9, 10 and 11).

Each mandrel 44 and is provided with spring pressed portions 44A and 45A respectively, engagingfaces'48 on. the mandrel 44, being adapted to engage and move the portions 45A, while the face '48 on themandrel 45, engages and movesthe portion 44A. When withdrawnthe parts-occupy the positions shown in Fig. 10 and when fully advanced to meeting and overlapping position, the parts occupy the positions indicated in Fig, 14, to form the joint 49.

With the arrival of the die block at station D,

the-mandrels are in place as shown in Figs. 5 --and 6, and-as the die cavity is-brought to :regiser with the bottom of hopper .50A,'powder is permittedtofiow therein until the cavity is'completely filled, including depression 42 in piece P. This completes the operation at station D.

The head is now advanced to station E, during which there'is no change in the relative positions of the piece forming elements.

During the dwell at station E, the fluid operated piston 31E causes thehead 38E to descend, t-he depending-studs 39E entering openings 15 'in die blocks'40, guide'the punch 16 to pressure position, 'formin the secondpiece'P2 and pressure welding the contacting portions, including the powder filled in the depressions 42. As the studs 39E are descending, their slotted cams 'B4engage pins'85 tfixed in the horizonta1 punches .and 8|, forcing the latter into engagement with the piece within the die and creating depressions on either side thereof and at different positions.

The up stroke of head 38E Withdraws the punch Hiand studs 39E, the latter permittingthe withdrawal of the punches 808I from the work'and dieby the action of cam slots84 and pins 85, assisted by coil springs 83. The die block 40 is now cleared and-readyfor advancing to the next station F.

During this next advance (stations E to F), the cams'69--'I0 force the racks 66 inward, turning the pinions 65 and stud shafts 62 against the action of their respective springs 64, and therewith eccentrically mounted pins 6|, causing the latter-to withdraw the two mandrels through cooperation with slots 60. At the same time, cam has guided roller 9| attached to the outer free end of arm 92 .to cause the movable portion 40A of die block 40 to move'outward and separate the die to release the completely formed piece. In

I2 these-relative positions, the headcomes to dwell at station F.

As the head 30 advances (stations IFto A), for the final operation, the 'dieplungers 53, 54 and 5 are caused to move upward together, carrying therewith the finished piece until the bottom thereof is slightly above the level of the top 'of die block 4i). In: this position, the piece is .carried forward until it contactsifixed wall v95, against which it is moved and cammed off the top of the die plungers by their continued advance until caught by chute'96 providing conveyance for the completed pieces. After the piece has been removed from the die plungers, the plungers are caused to descend and assume a positionas illustrated in Figs. 3 and 4 so that upon their arrival-at station A, they are again positioned for-a charge of powder to start another cycle .of operation. Coincident with the lowering of'the dieplungers, the camliflcauses roller 9| and therewith arm' 92 attached to die block portion 40A to move the latter back into closed position.

Throughout the present illustrations, we have shown the respectivepunches 4|, 43 and 1 6 operated from above to impart the compression strokes, 'as being single acting. 'In some cases, however, it may be desirable 'to use multiple punches to provide a means for proportioning the powder in'relation to the stroke'and/or in'certain die formations.

An'arrangement of parts to accomplish this is illustrated in Fig. 20, wherein the reciprocating hydraulic piston '31 is provided with a rack 10D meshing with a gear IOI attached'to ashaft 1'02 suitably supported in fixed frame 3|. Eccentrics let-I04 are also'carried on shaft lllt, and when rotated, impart a varied movement to die plungers H35, I06, which perform the same functions as punches 4|, 43 and 16, only multiple in their action. Such mechanism, while onlyshown and intended to rotate shaft 102, degrees and then reverse (or 360 degrees and then stop), could readily be extended to provide several revolutions of-the shaft in order that a quick'succession of similarblows could be delivered instead of-a single compression stroke.

In thesecond form of our inventionillustrated in Figs. '17 and 18, the operation is continuous, i. e., without dwells during the cycles. In this form, we have substantially inverted a plurality of moving die plunger elements such as use'd'below the rotating head in the first form, together with their stationary operating cams, and arranged them to travel in a circularpath cooper ating with similar die blocks and die plunger operating from below and travelling in circular paths as in the first form disclosed. These operating cam are supported from above by extensions of the fixed bearing members while the plungers and cross heads are supported in brackets carried by the rotating head. A continuous drive is substituted for the Geneva motion, and thepowder supply hoppers are offset, so as to be out of the path of travel of the upper dieplunger assemblies, and angularly arranged chutes convey the powder to the respective die cavities. Otherwise, the device is the same as in the first form.

Referring now to Figs. l'liand 18, the drawings show a rotatable head I30, supported and guided by stationary members I 3| and moving over roller bearings I32. "The head is securedto a vertical shaft I33 supported in a base plate I34, and a pinion [35 is likewise secured to shaft I33 and meshes with a driving gear [36, the shaft of 13 the latter being connected with any suitable power source (not shown).

All of the stationary bearing members I 3| extend upward and carry a circular supporting member I31 from which is hung a housing I38 wherein are formed cams I40, I4I, I42 and I43.

The first three mentioned cams respectively control .the reciprocating movements of die plungers I44, I45 and I46, while cam I43 controls the reciprocations of crosshead I41. Each of these upper die plunger assemblies are carried in suitable supports I48, the supports in turn being fixed to and carried by the rotating head I30.

The powder hoppers 50B and 500 are shown, each suitably supported in an oiTset position between two of the stationary supporting members I3I and angularly arranged chutes I48A are positioned to feed the powder to the cavities within the die blocks as they pass beneath them; Interchangeable ends I 49 are attached to the ends of the chutes and their open ends are shaped to correspond to the shape of the die cavities, thus when the die blocks are changed to make articles of difierent designs, the ends I49 are changed to agree with the design of the cavities in the die blocks.

The showing of a two hopper machine indicates a'two compression piece, if it is desired to build up a piece having more sections, a larger diameter is employed positioning additional sources of powder sup ply, one foreach compression.

As before stated, the design of the rotary head I30, the split die blocks and their operating cams, the mandrels and their operating cams and the under die plungers and their operating cams are all identical with those illustrated and described in connection with our first form, and we, therefore, will not redescribe their structures, operations or functions, other than to indicate like parts with like reference characters upon the drawings, and to refer thereto where necessary in the following description of the operation. 7

In the enlarged details, the only difi'erences will be in Figs. 3, 4, and 6, wherein the powder supply will be introduced from angular chutes, but the chute ends will be arranged identically as the hopper ends now shown, and in Figs. 2, '1 and 10 and 13, thesingle upper punches 4|, 43 and 16 will be replaced with the multiple punches I44, I45 and I46, and all cross heads will now be operated from cam I43 in place of pistons, as in the first form.

' In this second form, we have illustrated six sets of dies arranged about the circumferential path of travel, it being understood, however, that more or less can be substituted in accordance with the number of operations required to produce an individual piece. Inthe present showing, each die block produces a complete two pressure piece in each cycle of operation, without dwells of the head, the latter rotating continuously.

In operation, we will follow one die block in one complete cycle about its path of travel from the first powder introduction to the final ejection of the finished piece, it being understood that after the first cycle six individual pieces are in formation in the machine at the same time.

Powder is introduced to our selected die block cavity at G, Fig. 17, as the cavity moves under the chute ends I49, the separate areas 5I and 52' having been created by the positioning of the lower plungers 53, 54 and 55 during their travel over their respective cams 56, 51 and 58. As the head I30 passes position G and advances toward position H, the di plungers just mentioned are moved by their respective cams to assume positions as illustrated in Fig. '1, while the upper die plungers I 44, I45 and I46 under the influence of their respective cams I40, MI, and I 42, are relatively positioned so as to form a shape such as shown in punch M of the first form. In these positions, andguided by cross head I41, which latter is moved in unison with the upper die plungers under the influence of its cam I43, the upper die plungers enter the die block cavity and coacting with the lower die plungers, press the powder to the shape shownin section in Fig. 7, and indicated at P, which pressing operation takes place approximately in the position indicatcd at H.

With the continued advance of the head I toward position indicated at I, both sets of die plungers move down, carrying the initial compression of the piece bodily therewith until it is positioned as shown in section at the right hand side of Fig. 2, or at the station C, in that particularfigure. I With the continued advance of the head toward position J, the lower die plungers remain r stationary supporting the initial piece formae tion in its lowered position, while the upper die plungers, together with crosshead 4.1a, are moved upward out of lin of the chute of the'second powder hopper 50C. Coincident with this movement, cams 09 and 10 operate rack arms 66 and through the mechanism hereinbefore described in connection with the operation of the mandrels, causes mandrels 44 and 45 to moveover the piece P until they contact one another with their respective engaging faces 48 forming the overlapping joint 49 (see Figure 14).

At position J thedie block passes under the end I49 of chute I48A of th hopper 50C and receives its second charge of powder on top of the piece P and the overlapped mandrels. In this relative position, the head continues its ad vance toward position K, during-which the upper set of die plungers are respectively arranged through the action of their cams, to assume positions to correspond with the shape of the bottom of punch 16, Fig. 13. The crosshead I41 together with the arranged plungers is then caused to descend under the influence of its cam I 43, carrying therewith depending studs 39, and the respective upper die punches enterthe die cavity and compress the second chargeof powder to a shape such as shown in Figs. 13 and 14, to form piece P2 and pressure weld it to piece P, Coincident with this pressure from above, the slotted cams, 84, in the depending studs 39, contact pins and force the horizontal punches towardthe piece tov form the depressions on either side thereof, and as here shown in piece P. i With the continued advance of the head I30, the crosshead and upper die plungers are withdrawn permitting the horizontal punches to withdraw from the piece and the cams 69 and 10 also influence the withdrawal of mandrels 44 and 45 from the pressed formation. As soon as the mandrels are withdrawn, the cams 56, 51 and 58 cause the respective die plungers 53, 54 and 55 to align to form a flush top as shown in Fig. 16, and in this relative position, theymove upwardly together a sufiicient'height to raise the completed piece slightly above the top of the cavity and die block 40. Just prior to this -movement, the grooved cam moves the roller 9| on arm 92, away from head I30 to cause the split portion 40A of die block 40 to open and permit the ejece tion of the completed piece.

an adjustable powder cavity, means for automatically filling said cavity with powder, a rod reciprocably mounted above said cavity, fingers carried thereby, means for lowering the fingers to within the powder, and means for moving the fingers toward and away from the side walls of said cavity after entering the powder.

8. In a machine of the character described, a powder cavity, means for filling said cavity with powder, reciprocating means aligned with the cavity, a slidable casing carried thereby and adapted to coact with said cavity to retain the powder therein, fingers carrier by said reciprocating means and adapted to enter the powder, and operable connections between the fingers and the slidable casing whereby the fingers are caused to operate toward and away from the side walls of said cavity within the powder by the positioning of the casing and the coaction of the reciproeating means.

9. In a machine for compressing powder into solid shapes which comprises a powder mold cavity, means for introducing charge of powder into said cavity, means for applying forming pressure to the powder in said cavity, means for introducing a second charge of powder into said cavity, means comprising pivoted fingers, and means mounting said fingers for introducing them from above the second charge of powder into said second charge of powder for hilling up the powder and increasing the concentration of powder in areas of the mold cavity to strengthen the points of unison during the pressure weld, and means to compact and weld by a pressure operation said layers into a unitary article.

10. In a machine for compressing powder into solid shapes which comprises a powder mold cav- 18 ity, means for introducing a charge of powder into said cavity, means for applying forming pressure to the powder in said cavity, means for introducing a second charge of powder into said cavity, means comprising pivoted fingers, and means mounting said fingers for introducing them from above the second charge of powder into said second charge of powder for billing up the powder and increasing the concentration of powder in areas of the mold cavity to strengthen the points of unison during the pressure weld, and means to compact and weld by a pressure operation said layers into a, unitary article, said last named means including means for causing diiferent forming pressures to be applied to each powder charge.

JOSEPH S. PECKER.

HENRY A. SIMPSON.

REFERENCES CITED The following references are of record in the file of this patent:

UNI'I'ED STATES PATENTS Number Name Date 613,758 Clark Nov. 8, 1898 778,483 Flood Dec. 27, 1904 1,595,369 Wasmer Aug. 10, 1926 1,599,085 Gibson Sept. 7, 1926 1,661,008 Payne Feb. 28, 1928 1,803,814 Spengler et a1. May 5, 1931 2,260,456 Johnson Oct. 28, 1941 2,325,687 Kux Aug. 3, 1943 FOREIGN PATENTS Number Country Date 471,306 France July 7, 1914 

